// 电池健康评估
export default {
  'batteryVoltage.no': 'Code',
  'batteryVoltage.tableNo': 'S/N',
  'batteryVoltage.cluster': 'Cluster',
  'batteryVoltage.sum': 'Total',
  'batteryVoltage.vol.title': 'Voltage Consistency',
  'batteryVoltage.vol.voltageDate': 'Date',
  'batteryVoltage.vol.distributionMap': 'Consistency Distribution',
  'batteryVoltage.vol.boxTotalNum': 'Number of boxes ',
  'batteryVoltage.vol.clusterTotalNum': 'Number of clusters ',
  'batteryVoltage.vol.reportName': 'Add the assessment for the day to the monthly health report',
  'batteryVoltage.vol.standard': 'Standard description',
  'batteryVoltage.vol.chargeLevel': 'Charge',
  'batteryVoltage.vol.clusterNum': 'Number of clusters ',
  'batteryVoltage.cycle.cycleTimes': 'Cycle count',
  'batteryVoltage.vol.clusterName': 'Cluster name',
  'batteryVoltage.vol.dischargeLevel': 'Discharge',
  'batteryVoltage.vol.comprehensiveLevel': 'Overall',
  'batteryVoltage.vol.comprehensiveScore': 'Overall score',
  'batteryVoltage.vol.uniformity': 'Consistency',
  'batteryVoltage.vol.search': 'Search',
  'batteryVoltage.vol.excellent': 'excellent',
  'batteryVoltage.vol.good': 'good',
  'batteryVoltage.vol.average': 'medium',
  'batteryVoltage.vol.poor': 'bad',
  'batteryVoltage.vol.other': 'other',
  'batteryVoltage.vol.overall': 'Overall Distribution',
  'batteryVoltage.vol.highest': ' ',
  'batteryVoltage.vol.details': 'Assessment Detail',
  'batteryVoltage.vol.clusterCode': 'Cluster code',
  'batteryVoltage.temp.title': 'Temperature Consistency',
  'batteryVoltage.soc.title': 'SOC Consistency',
  'batteryVoltage.soc.monitorTable': 'SOC Monitoring Data Table For Cluster',
  'batteryVoltage.soc.illustrate':
    '1. The average SOC value of the cluster is: 0%\n' +
    '2. Among them, the number of clusters with a mean SOC value of ± 5% is 0\n' +
    '(as highlighted in the table above), and their SOC data will be verified and compared for analysis, as shown in ② and ③\n' +
    '3. Only supports verifying SOC data with historical dates (does not support  verifying data for the day)',
  'batteryVoltage.soc.dataTable': 'SOC Monitoring Data Table For Key Cluster',
  'batteryVoltage.soc.analyzeResult':
    'The Comparative Analysis Results Of Monitoring Data And Verification Data Are As Follows',
  'batteryVoltage.soc.object': 'Verification object',
  'batteryVoltage.soc.compareValue': 'Comparison value(monitoring data)',
  'batteryVoltage.soc.compareResult': 'Comparison result',
  'batteryVoltage.soc.comparedValue': 'Compared value (verification data)',
  'batteryVoltage.soc.conclusion': 'Conclusion',
  'batteryVoltage.soc.illustrate2':
    'Explanation: 1. When the comparison results exceed the ± threshold by 10%, \n' +
    'the SOC consistency assessment data for the day will be automatically added to the monthly health assessment report.\n' +
    '2. The comparison result threshold can be modified in "Report Analysis - Parameter Settings".',
  'batteryVoltage.cluster.title': 'Cluster Current Consistency',
  'batteryVoltage.cluster.stackCurve':
    'Max Current Difference Curve During Charging & Discharging Of Stacks',
  'batteryVoltage.cluster.clusterCurve': 'Real-time Current Curve Of Clusters',
  'batteryVoltage.cluster.from': 'From the graph, it is concluded that :',
  'batteryVoltage.cluster.illustrate':
    'Explanation: When the comparison results exceed the ± threshold by 5%, the consistency evaluation data of the current cluster on that day will be automatically added to the monthly health assessment report.\n' +
    '2. The comparison result threshold can be modified in "Report Analysis - Parameter Settings".',
  'batteryVoltage.capacity.title': 'Capacity Consistency',
  'batteryVoltage.capacity.time': 'Recent assessment time for "remaining capacity consistency"',
  'batteryVoltage.capacity.update': 'Update SOH Data',
  'batteryVoltage.capacity.sumTable': 'Statistical Table For Remaining Capacity Of  Stacks',
  'batteryVoltage.capacity.rate': 'SOH Ratio Of Remaining Capacity To Rated Capacity ',
  'batteryVoltage.cycle.title': 'Cycle Life',
  'batteryVoltage.cycle.station': 'SOH of plant',
  'batteryVoltage.cycle.maxActualCapacity':
    'The current actual max remaining capacity of the plant',
  'batteryVoltage.cycle.maxVolCapacity':
    'The max remaining capacity of the recently evaluated plant',
  'batteryVoltage.cycle.compareReduce': 'Reduced comparison results',
  'batteryVoltage.cycle.sohReduceChart': 'Trend chart of SOH attenuation in power plants',
  'batteryVoltage.cycle.sohModelValue': 'SOH value of battery cell model',
  'batteryVoltage.cycle.comSohModelValue': 'SOH values of the comprehensive power plant model',
  'batteryVoltage.cycle.esSohModelValue': 'Estimated SOH value of the power plant',
  'batteryVoltage.cycle.sohTrendChart': 'Detailed chart of SOH trend',
  'batteryVoltage.cycle.as': 'As of',
  'batteryVoltage.cycle.comToModel':
    'Integrated model SOH value of power plant - cell model SOH value',
  'batteryVoltage.cycle.dayToYes':
    'The difference between the SOH value of the comprehensive model of the plant and the previous day',
  'batteryVoltage.cycle.remark':
    'By comparing the daily trend of SOH between "daily SOH" and "previous day SOH"',
  'batteryVoltage.cycle.result': 'Come to conclusion',
  'batteryVoltage.safe.title': 'Safety Operation',
  'batteryVoltage.safe.station': 'Power Plant',
  'batteryVoltage.safe.stack': 'Battery Stack',
  'batteryVoltage.safe.cycle': 'Cycle count',
  'batteryVoltage.safe.year': 'Year',
  'batteryVoltage.safe.month': 'Month',
  'batteryVoltage.safe.quarter': 'Quarter',
  'batteryVoltage.safe.technicalIndex': 'Technical Index',
  'batteryVoltage.safe.onGrid': 'On-grid energy ',
  'batteryVoltage.safe.offGrid': 'Off-grid energy ',
  'batteryVoltage.safe.hours': 'Operating hours',
  'batteryVoltage.safe.utilization': 'Equivalent utilization factor',
  'batteryVoltage.safe.frequency': 'Equivalent discharge times',
  'batteryVoltage.safe.efficiency': 'Energy Dfficiency Index',
  'batteryVoltage.safe.overEfficiency': 'Overall efficiency',
  'batteryVoltage.safe.lossRate': 'Loss rate',
  'batteryVoltage.safe.roundtrip': 'Charge-discharge roundtrip efficiency',
  'batteryVoltage.safe.rateToSoh': 'Energy retention rate assessment/SOH assessment',
  'batteryVoltage.safe.reliability': 'Reliability Index ',
  'batteryVoltage.safe.availability': 'Availability factor',
  'batteryVoltage.safe.utilizationSta': 'Utilization factor',
  'batteryVoltage.safe.failureRate': 'Failure rate of battery ',
  'batteryVoltage.safe.failureFrequency': 'Relative failure frequency of battery stack',
  'batteryVoltage.safe.suggestions': 'Suggestion',
  'batteryVoltage.safe.chargeCapacity': 'Charge energy',
  'batteryVoltage.safe.dischargeCapacity': 'Discharge energy',
  'batteryVoltage.safe.stackHours': 'Operating hours',
  'batteryVoltage.safe.stackEquivalent': 'Equivalent utilization factor',
  'batteryVoltage.safe.stackFrequency': 'Equivalent discharge times',
  'batteryVoltage.safe.stackLose': 'Battery stack loss rate',
  'batteryVoltage.safe.stackConversion': 'Charge-discharge roundtrip efficiency',
  'batteryVoltage.safe.energyToSoh': 'Energy retention rate assessment/SOH assessment',
  'batteryVoltage.safe.stackAvailability': 'Availability factor',
  'batteryVoltage.safe.stackUtilization': 'Utilization factor',
  'batteryVoltage.safe.batteryFailureRate': 'Failure rate of battery',
  'batteryVoltage.safe.indivual': ' ',
  'batteryVoltage.tips.one':
    'The charge-discharge grades in the table are divided into four grades: A, B, C, and D. which are represents at the extreme case of charge-discharge,with excellent,good,moderate, poor voltage consistency;',
  'batteryVoltage.tips.two':
    'The comprehensive grade is composed of charge-discharge grades, which are divided into 9 grades according to the following rules:',
  'batteryVoltage.tips.three':
    'Consistency is an assessment of the comprehensive grade, with scores of 100, 90, 80, 70, 60, 50, 40, 30, and 20 corresponding to the descending order of level 9 in 2. Scores (80, 100) are considered excellent, 60, and 80 are considered good, [40, 60] are considered moderate, and (0, 40) are considered poor.',
  'batteryVoltage.tips.four': 'Evaluate based on the following standard:',
  'batteryVoltage.tips.five': 'Temp range distribution',
  'batteryVoltage.tips.six': 'Grade evaluation',
  'batteryVoltage.tips.seven': 'Standard deviation distribution',
  'batteryVoltage.tips.eight': 'Voltage range distribution',
  'batteryVoltage.tips.soc': 'SOC consistency assessment process:',
  'batteryVoltage.tips.socOne': 'Step 1: Monitor the real-time SOC of the entire cluster,',
  'batteryVoltage.tips.socOneAfter': '% and mark&check the clusters average SOC value；',
  'batteryVoltage.tips.socTwo':
    'Step 2: Use modular algorithms to recalculate SOC for the selected clusters with key annotations;',
  'batteryVoltage.tips.socThree':
    'Step 3: Compare the SOC recalculated by the cluster with the SOC monitored in Step 1. If the comparison result exceeds the ±',
  'batteryVoltage.tips.socThreeAfter':
    '%,it is determined that the SOC consistency of the current cluster is not the same;',
  'batteryVoltage.tips.socFour':
    'Step 4: When SOC consistency is different, it will be automatically added to the monthly health report for a detailed analysis of the reasons and provide guidance.',
  'batteryVoltage.tips.socFive': 'Standard for selecting evaluation objects',
  'batteryVoltage.tips.socSix': 'SOC inconsistency determination standard',
  'batteryVoltage.tips.socSeven': 'The comparison result exceeds the threshold by',
  'batteryVoltage.tips.socEight': '1.The average SOC value of the cluster is:',
  'batteryVoltage.tips.socNight': '2.Among them, the number of clusters with a mean SOC value of ±',
  'batteryVoltage.tips.socNightMiddle': '%(as highlighted in the table above)',
  'batteryVoltage.tips.socNightAfter':
    'and their SOC data will be verified and compared for analysis, as shown in ② and ③',
  'batteryVoltage.tips.socTen':
    '3.Only supports verifying SOC data with historical dates (does not support  verify data for the day)',
  'batteryVoltage.tips.socEle': 'Cell Name',
  'batteryVoltage.tips.socTwe': 'Cell Code',
  'batteryVoltage.tips.socThi': 'SOC verification data value',
  'batteryVoltage.tips.socFor': 'Explanation',
  'batteryVoltage.tips.socFif': '1. When the comparison results exceed the ± threshold by',
  'batteryVoltage.tips.socFifAfter':
    '%, the SOC consistency assessment data for the day will be automatically added to the monthly health assessment report.',
  'batteryVoltage.tips.socSixteen':
    'The comparison result threshold can be modified in "Report Analysis - Parameter Settings".',
  'batteryVoltage.tips.socSev': 'Module',
  'batteryVoltage.tips.cluOne': 'Cluster current consistency evaluation process',
  'batteryVoltage.tips.cluTwo':
    'Step 1: Monitor the real-time maximum current difference of the entire plant during the charge-discharge process, and highlight the piles with "cluster current difference exceeding the average value";',
  'batteryVoltage.tips.cluThree':
    'Step 2: Conduct a detailed trend analysis of the current in the clusters of the highlighted stacks;',
  'batteryVoltage.tips.cluFour':
    'Step 3: When the maximum current difference of the cluster occurs within the current month, it will be automatically added to the "Monthly Health Report". If the corresponding circulation exceeds',
  'batteryVoltage.tips.cluFive':
    '% of the set rated current threshold, it will be highlighted for explanation and analysis, and guidance will be provided',
  'batteryVoltage.tips.cluSix': 'exceeds the average current difference',
  'batteryVoltage.tips.cluSeven': 'The criterion for determining inconsistent cluster currents',
  'batteryVoltage.tips.cluEight':
    'the circulating current of the cluster exceeds the threshold by ',
  'batteryVoltage.tips.cluNight': 'Current difference',
  'batteryVoltage.tips.cluTen': 'Average current difference',
  'batteryVoltage.tips.cluEle': 'Max current difference',
  'batteryVoltage.tips.cluTwe': ' From the graph, it is concluded that the heaps (number',
  'batteryVoltage.tips.cluTweAfter':
    '(marked with coordinates) with cluster current difference exceeding the mean/circulation difference greater than the threshold are analyzed as follows:',
  'batteryVoltage.tips.cluThr': ' When the comparison results exceed the ± threshold by',
  'batteryVoltage.tips.cluThrAfter':
    '%, the consistency evaluation data of the current cluster on that day will be automatically added to the monthly health assessment report.',
  'batteryVoltage.tips.cluFourth': 'Max circulation difference of the day (A)',
  'batteryVoltage.tips.cluFifth': 'Duration',
  'batteryVoltage.tips.cluSixth': 'Max circulation difference',
  'batteryVoltage.tips.cluSevth': 'Average value',
  'batteryVoltage.tips.cluEigth': 'Current',
  'batteryVoltage.tips.SOH': 'Update SOH Data',
  'batteryVoltage.tips.sys':
    'System prompt: Please choose the correct maintenance time cycle, otherwise the accuracy of the data cannot be guaranteed.',
  'batteryVoltage.tips.maintain': 'Select maintenance time cycle',
  'batteryVoltage.tips.update': 'Update',
  'batteryVoltage.tips.none': 'None',
  'batteryVoltage.cancel': 'Cancel',
  'batteryVoltage.capcityText': 'Capacity consistency assessment process:',
  'batteryVoltage.capcityS1': 'Step 1: Calculate the rated capacity of the entire battery stack;',
  'batteryVoltage.capcityS2':
    'Step 2: Calculate the remaining capacity of the entire battery stack;',
  'batteryVoltage.capcityS3':
    'Step 3: Calculate the State of Health (SOH) of the reactor based on its rated capacity and remaining capacity;',
  'batteryVoltage.capcityS4':
    'Step 4: Divide the SOH values of each pile into different range values and label them in the form of pie charts/color charts',
  'batteryVoltage.ScoupeTitle': 'SOH value division range:',
  'batteryVoltage.Scoupe1': 'Scope 1',
  'batteryVoltage.Scoupe2': 'Scope 2',
  'batteryVoltage.Scoupe3': 'Scope 3',
  'batteryVoltage.Scoupe4': 'Scope 4',
  'batteryVoltage.cycleTitle': 'Cycle life assessment process:',
  'batteryVoltage.cycleS1':
    'Step 1: Based on the operating data within the required time range, combined with laboratory cell cycle testing parameters, calculate the estimated cell model curve',
  'batteryVoltage.cycleS2':
    'Step 2: Based on the comprehensive SOH values of historical plants that have been evaluated within the required time range, deduce the predicted SOH values for future stations',
  'batteryVoltage.cycleS3':
    'Step 3: Compare the required comprehensive SOH of the specific plant with the SOH of the battery cell model during the same period, compare it with the comprehensive SOH of the previous cycle, and check the trend of changes.',
  'batteryVoltage.cycleS4':
    'Step 4: If the difference is greater than the setting of threshold (5%), it indicates that there may be some problems in the evaluation of the station comprehensive model SOH and the cell model SOH. If the model is verified to have no problems, it indicates that the poor consistency of the power station has affected the overall capacity',
  'batteryVoltage.cycleS5': 'Comparison result',
  'batteryVoltage.cycleS6': 'Determine based on the following standard:',
  'batteryVoltage.none': 'None',
  'batteryVoltage.GBTitle':
    'Reference Document<GB/T 36549-2018 Operation performance index and evaluation of electrochemicl energy storage station>',
  'batteryVoltage.GBTitleS': 'Calculation rules for operating coefficient',
  'batteryVoltage.GBR1': 'In the formula:',
  'batteryVoltage.GBR2': 'Equivalent utilization factor of energy storage station,%;',
  'batteryVoltage.GBR3': 'Rated power of energy storage station, kW;',
  'batteryVoltage.GBR4': 'The rated power of the i-th energy storage unit, kW;',
  'batteryVoltage.GBR5': 'Equivalent utilization factor of the i-th energy storage unit,%',
  'batteryVoltage.GBR6':
    'The charge amount of the i-th energy storage unit during the evaluation period, kW · h',
  'batteryVoltage.GBR7':
    'The discharge capacity of the i-th energy storage unit during the evaluation period, kW · h',
  'batteryVoltage.GBR8': 'The rated power of the i-th energy storage unit, kW;',
  'batteryVoltage.GBR9':
    'Count the number of hours in the evaluation period, in hours (h). When the evaluation period is one year, PH is taken as 8760h',
  'batteryVoltage.GBR10': 'Considering the calculation rules comprehensively',
  'batteryVoltage.GBR11': 'Comprehensive efficiency of energy storage station,%',
  'batteryVoltage.GBR12':
    'Evaluate the on grid electricity consumption of energy storage stations during the evaluation period, kW · h',
  'batteryVoltage.GBR13':
    'Evaluate the off grid electricity consumption of energy storage stations during the evaluation period,kW · h',
  'batteryVoltage.decay': 'Decay date',
  'batteryVoltage.updateSOC': 'Updated SOH data successfully',
  'batteryVoltage.noCapacity':
    'There is no data during this period, please adjust the period again!',
  'batteryVoltage.suggestions': 'Suggestions for improving capacity consistency',
  'batteryVoltage.installBC':
    'Install a BC system to enhance active balancing technology, monitor the voltage and temp information of each battery cells in real-time, and minimize the inconsistency problem of battery series connection.',
  'batteryVoltage.resultAuto': 'The evaluation results have been updated to',
  'batteryVoltage.monthReport': 'Monthly Health Assessment Report',
  'batteryVoltage.exceed30': 'Time selection cannot exceed 30 days',
  'batteryVoltage.SOHPlant': 'SOH value of plant model (%)',
  'batteryVoltage.SOHPlantModel': 'SOH value of plant model - SOH value of cell model (%)',
  'batteryVoltage.SOHPlantDiff': 'SOH difference from yesterday(%)',
  'batteryVoltage.SOHPlantDiffMonth': 'SOH difference from past month',
  'batteryVoltage.SOHPlantDiffYear': 'SOH difference from past year',
  'batteryVoltage.SOHDiffPastDay': 'Estimated SOH difference from yesterday',
  'batteryVoltage.SOHDiffPastMonth': 'Estimated SOH difference from last month',
  'batteryVoltage.SOHDiffPastYear': 'Estimated SOH difference from last year',
  'batteryVoltage.SOHDiffAllPastDay': "Estimated SOH difference from yesterday's actual SOH",
  'batteryVoltage.SOHDiffAllPastMonth': "Estimated SOH difference from last month's actual SOH",
  'batteryVoltage.SOHDiffAllPastYear': "Estimated SOH difference from last year's actual SOH",
  'batteryVoltage.concluded': 'Concluded that:',
  'description.day':
    "By comparing 'Current {dateType} SOH' with 'Estimated SOH', 'Yesterday's {dateType} SOH', and the SOH trend of each {dateType},",
  'description.month':
    "By comparing 'Current {dateType} SOH' with 'Estimated SOH', 'Last {dateType} SOH', and the SOH trend of each {dateType},",
  'description.year':
    "By comparing 'Current {dateType} SOH' with 'Estimated SOH', 'Last Year's {dateType} SOH', and the SOH trend of each {dateType},",
  'batteryVoltage.vol.total': 'Total',
  'batteryVoltage.vol.tips':
    'There is no capacity assessment data during this period. Please adjust the period again',
  'batteryVoltage.vol.to': 'to',
  'batteryVoltage.vol.cc': 'Capacity Consistency',
  'batteryVoltage.vol.suggestions':
    'Install a BC system to improve active balancing technology, monitor the voltage, temperature and other information of each single battery in real time, and minimize the inconsistency problem of battery series connection.',
  'batteryVoltage.safe.s1': 'The total amount of charge on the DC side of the battery stack unit',
  'batteryVoltage.safe.s2':
    'The total amount of discharge on the DC side of the battery stack unit',
  'batteryVoltage.safe.s3':
    'The operating time of the battery stack unit is the actual operating power/rated power * time value of the battery stack energy storage',
  'batteryVoltage.safe.s4': '(Charge energy+discharge energy)/(Rated power * Evaluation time)',
  'batteryVoltage.safe.s5':
    'Historical total discharge capacity of battery stack/rated capacity of power station',
  'batteryVoltage.safe.s6':
    'The ratio of total electrical energy loss to discharge capacity during the charging, discharging, and energy storage processes of battery stack units',
  'batteryVoltage.safe.s7':
    'The ratio of total discharge energy to total charge energy of battery stack units',
  'batteryVoltage.safe.s8': 'Query the latest SOH value of the day within the scope',
  'batteryVoltage.safe.s9':
    'The ratio of the available time of battery stack units to the statistical time, where the available time is the total time minus the fault time',
  'batteryVoltage.safe.s11':
    'The ratio of the operating time of battery stack units to the statistical time',
  'batteryVoltage.safe.s12':
    'The ratio of the number of failed individual cells in battery stack to the total number of individual cells in the stack',
  'batteryVoltage.safe.s13':
    'The total amount of electricity transmitted from the power station to the grid',
  'batteryVoltage.safe.s14':
    'The total amount of electricity received by the power station from the grid',
  'batteryVoltage.safe.s15':
    'The operating time of energy storage units is calculated by weighting the actual operating power/rated power * time value of each energy storage unit, and then averaging the results',
  'batteryVoltage.safe.s16':
    'Calculate the equivalent utilization coefficient of each energy storage unit during the evaluation period, and then weight the average according to the rated power',
  'batteryVoltage.safe.s17':
    'Historical total discharge of the power station/rated capacity of the power station',
  'batteryVoltage.safe.s18':
    'The ratio of on grid electricity to off grid electricity during the operation of the power station',
  'batteryVoltage.safe.s19':
    'The ratio of the total energy loss during the charging, discharging, and energy storage processes of the energy storage unit to the amount of electricity stored on the grid',
  'batteryVoltage.safe.s20':
    'The ratio of the total discharge capacity to the total charge capacity of the energy storage unit',
  'batteryVoltage.safe.s21': 'Query the latest SOH value of the day within the scope',
  'batteryVoltage.safe.s22':
    'The ratio of the available time of the power station to the statistical time, where the available time is the total time minus the fault time. The fault time is considered to be the time when half of the reactors fail at the same time, which is recognized as the power station fault time',
  'batteryVoltage.safe.s23':
    'The ratio of the operating time of the power station to the statistical time',
  'batteryVoltage.safe.s24':
    'The ratio of the number of failed individual batteries to the total number of individual batteries',
  'batteryVoltage.safe.s25':
    'The ratio of the number of failures in the energy storage unit battery stack to the total number of battery stacks in the unit',
  'batteryVoltage.safe.times': ' ',
  'batteryVoltage.vol.score': ' ',
};
